Rotating optical range finder

ABSTRACT

A rotating optical range finder includes a stationary base, a rotating base, an optical sensor, a transmitting circuit, a receiving circuit, a first induction coil, and a second induction coil. The rotating base s disposed on the stationary base. The optical sensor is disposed in the rotating base. The transmitting circuit is disposed in the stationary base. The receiving circuit is disposed in the rotating base and electrically connected to the optical sensor. The first induction coil is disposed in the stationary base and electrically connected to the transmitting circuit. The second induction coil is disposed in the rotating base and electrically connected to the receiving circuit.

RELATED APPLICATIONS

This application claims priority to Taiwan Application Serial Number104204238, filed Mar. 20, 2015, the entirety of which is hereinincorporated by reference.

BACKGROUND

1. Technical Field

The present disclosure relates to an optical range finder, and moreparticularly, to a rotating optical range finder.

2. Description of Related Art

Distance measurement can be performed by direct measurement with a ruleror triangulation. Due to the limitation in length, the ruler is notsuitable to measure a long distance. Triangulation is applicable tomeasure a long distance, but two persons are required in the measurementin that the observation mark is setup by a person, and the measuringinstrument is controlled by another one. Further, it is troublesome toincur a larger error as conducting a longer distance measurement.

Recently, laser range finders are more and more popular for the distancemeasurement, and thus becomes one of the most important tools indistance measurement. Principally, the laser range finder sends a laserpulse of a narrow beam toward an object and measures the time taken bythe pulse to be reflected from the object and back to the sender.

SUMMARY

This disclosure provides a rotating optical range finder in which thepower transfer is achieved by wireless means with a first induction coiland a second induction coil. Therefore, no other electric power transfercomponent is needed to be disposed between the stationary base and therotating base, such that the rotating base becomes easier to rotate andthat the rotating optical range finder becomes more durable.

In one aspect of the disclosure, a rotating optical range finder isprovided The rotating optical range finder includes a stationary base, arotating base, an optical sensor, a transmitting circuit, a receivingcircuit, a first induction coil, and a second induction coil. Therotating base is disposed on the stationary base. The optical sensor isdisposed in the rotating base. The transmitting circuit is disposed inthe stationary base. The receiving circuit is disposed in the rotatingbase and electrically connected to the optical sensor. The firstinduction coil is disposed in the stationary base and electricallyconnected to the transmitting circuit. The second induction coil isdisposed in the rotating base and electrically connected to thereceiving circuit.

In one or more specific embodiments, the first induction coil and thesecond induction coil perform wireless power transfer.

In one or more embodiments, the first induction coil and the secondinduction coil perform wireless power transfer by magnetically coupledresonance.

In one or more specific embodiments, the first induction coil and thesecond induction coil perform wireless signal transfer.

In one or more specific embodiments, the first induction coil and thesecond induction coil have the same symmetry axis.

In one or more specific embodiments, a ratio of dimensions of the firstinduction coil and the second induction coil is from about 1 to about 2.

In one or more specific embodiments, in the rotating optical rangefinder, there is a gap between the first induction coil and the secondinduction coil, and the gap is less than a radius of a smallestinscribed circle of the first induction coil or the second inductioncoil.

In one or more specific embodiments, the rotating optical range finderfurther includes a light-emitting component disposed in the stationarybase. The optical sensor includes a first reflector, a second reflector,a light-receiving lens, and an image sensor. The first reflector isconfigured to receive and reflect a light emitted by the light-emittingcomponent. The second reflector is configured to receive a lightreflected by the first reflector and reflect the light reflected by thefirst reflector to an object. The light-receiving lens is configured tocollect a light reflected by the object. The image sensor is configuredto detect a light collected by the light-receiving lens.

In one or more specific embodiments, the light-emitting component is acollimated beam laser module.

In one or more specific embodiments, the rotating base has a firstrotation axis, and the light-emitting component and the first reflectorare disposed on the first rotation axis.

In one or more specific embodiments, the first reflector rotates aboutthe first rotation axis, and the second reflector has a second rotationaxis and is configured to perform an orientation adjustment by rotatingabout the second rotation axis.

In one or more specific embodiments, the first rotation axis isperpendicular to the second rotation axis.

In one or more specific embodiments, the rotating base has a firstthrough hole, and the stationary base has a second through hole. Thefirst through hole and the second through hole form a passage, such thata light emitted by the light-emitting component passes the passage andreaches the first reflector.

In one or more specific embodiments, the rotating optical range finderfurther includes a light-emitting component emitting a light to anobject. The rotating optical range finder is disposed in the rotatingbase, and the optical sensor detects a light reflected by the object.

In one or more specific embodiments, the optical range finder furtherincludes a plurality of optical data transmission devices in both therotating base and the stationary base performing wireless signaltransfer between the rotating base and the stationary base.

The rotating optical range finder is continuously rotating when thedistances between the optical range finder and surroundings aremeasured. By performing wireless power transfer by the first inductioncoil and the second induction coil, no other electric power transfercomponent, such as a slip ring, is needed between the stationary baseand the rotating base. Therefore, the weight of the rotating base islessened, and the volume of the rotating base is reduced. Moreover,because there is no physical component disposed between the stationarybase and the rotating base to perform electric power transfer, fractionsbetween the stationary base and the rotating base is lessened.Therefore, the rotating base becomes easier to rotate

It is to be understood that both the foregoing general description andthe following detailed description are by examples, and are intended toprovide further explanation of the invention as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention can be more fully understood by reading the followingdetailed description of the embodiment, with reference made to theaccompanying drawings as follows:

FIG. 1 is a schematic perspective view of a rotating optical rangefinder according to one embodiment of this invention;

FIG. 2 is a schematic perspective cross-sectional view of the rotatingoptical range finder according to one embodiment of this invention;

FIG. 3 is a schematic view of the rotating optical range finderaccording to one embodiment of this invention; and

FIG. 4 is a schematic view of the rotating optical range finderaccording to another embodiment of this invention.

DETAILED DESCRIPTION

In the following detailed description, for purposes of explanation,numerous specific details are set forth in order to provide a thoroughunderstanding of the disclosed embodiments. It will be apparent,however, that one or more embodiments may be practiced without thesespecific details.

In other instances, well-known structures and devices are schematicallydepicted in order to simplify the drawings.

FIG. 1 is a schematic perspective view of a rotating optical rangefinder 100 according to one embodiment of this invention. A rotatingoptical range finder 100 is provided. The rotating optical range finder100 measures distances between the rotating optical range finder 100 andsurroundings. The rotating optical range finder 100 can rotateall-round, so the rotating optical range finder 100 can measuredistances between the rotating optical range finder 100 and thesurroundings. The rotating optical range finder 100 can be used in arobot module. By measuring the distances between the rotating opticalrange finder 100 and the surroundings, the rotating optical range finder100 provides the obstacle detection that is needed by the robot module.

FIG. 2 is a schematic perspective cross-sectional view of the rotatingoptical range finder 100 according to one embodiment of this invention.FIG. 3 is a schematic view of the rotating optical range finder 100according to one embodiment of this invention. FIGS. 2 and 3 are viewedfrom the perspective V of FIG. 1. As shown in FIGS. 2 and 3, therotating optical range finder 100 includes a stationary base 110, arotating base 120, an optical sensor 130, a transmitting circuit 140, areceiving circuit 150, a first induction coil 160, and a secondinduction coil 170. The rotating base 120 is disposed on the stationarybase 110. The optical sensor 130 is disposed in the rotating base 120.The transmitting circuit 140 is disposed in the stationary base 110. Thereceiving circuit 150 is disposed in the rotating base 120 andelectrically connected to the optical sensor 130. The first inductioncoil 160 is disposed in the stationary base 110 and electricallyconnected to the transmitting circuit 140. The second induction coil 170is disposed in the rotating base 120 and electrically connected to thereceiving circuit 150.

Specifically, the first induction coil 160 and the second induction coil170 perform wireless power transfer. More specifically, the firstinduction coil 160 and the second induction coil 170 perform wirelesspower transfer by magnetically coupled resonance.

After a current is generated by the transmitting circuit 140, thecurrent flows to the first induction coil 160, and the first inductioncoil 160 generates corresponding electromagnetic fields. Then,magnetically coupled resonance is generated between the first inductioncoil 160 and the second induction coil 170, such that the electric powerin the first induction coil 160 is transmitted to the second inductioncoil 170 via the electromagnetic fields and that a current is generatedin the second induction coil 170 as well, which will flows to thereceiving circuit 150. Finally, the current flows to the optical sensor130 to provide electric power needed by the optical sensor 130.

The rotating optical range finder 100 is continuously rotating when thedistances between the optical range finder 100 and the surroundings aremeasured. Then, by performing wireless power transfer by the firstinduction coil 160 and the second induction coil 170, no other electricpower transfer component, such as a slip ring, is needed to be disposedbetween the stationary base 110 and the rotating base 120. Therefore,the weight of the rotating base 120 is lessened, and the volume of therotating base 120 is reduced. Moreover, because there is no physicalcomponent disposed between the stationary base 110 and the rotating base120 to perform electric power transfer, fractions between the stationarybase 110 and the rotating base 120 is lessened. Therefore, the rotatingbase 120 becomes easier to rotate.

In addition, if there are electric power transfer components, such asthe brushes and the metal ring, disposed between the stationary base 110and the rotating base 120, the brushes and the metal ring are pressedagainst each other when the rotating base 120 is rotating. Then, thebrushes and the metal ring will be worn in the long term, and scrapswill be generated, resulting in electrical leakage or short circuit. Ifthe first induction coil 160 and the second induction coil 170 areadopted to perform wireless power transfer, the aforementioned problemcan be avoided, such that the rotating optical range finder 100 becomesmore durable.

Compared to other electric power transfer components such as the blushesand the metal ring, the costs of the first induction coil 160 and thesecond induction coil 170 are lower. Therefore, by using the firstinduction coil 160 and the second induction coil 170, the cost of therotating optical range finder 100 is reduced.

The first induction coil 160 and the second induction coil 170 mayperform wireless signal transfer as well. Specifically, when a currentis generated in the transmitting circuit 140, the current carries signalas well. Then, the current flows to the first induction coil 160, andthe first induction coil 160 generates the corresponding electromagneticfields. Then, magnetically coupled resonance is generated between thefirst induction coil 160 and the second induction coil 170, such thatthe electric power in the first induction coil 160 is transmitted to thesecond induction coil 170 via the electromagnetic fields and that thecurrent is generated in the second induction coil 170 as well. At thesame time, because the amplitudes of the current in the first inductioncoil 160 changes with time, the corresponding electromagnetic fieldschange with time as well. Therefore, the magnitude of the currentgenerated in the second induction coil 170 also changes with time, andthe way the magnitude of the current generated in the first inductioncoil 160 changes with time is the same as the way the magnitude of thecurrent generated in the second induction coil 170 changes with time.Accordingly, the signal carried by the current generated by thetransmitting circuit 140 is transferred from the first induction coil160 to the second induction coil 170 via the electromagnetic fields. Thesignal may be further sequentially transferred to the receiving circuit150 and the optical sensor 130 from the second induction coil 170.

On the other hands, signals generated by the optical sensor 130 may alsobe sequentially transferred to the receiving circuit 150 and the secondinduction coil 170. Then, the signals may be sequentially transferred tothe first induction coil 160 and the transmitting circuit 140 via theelectromagnetic fields.

In particular, the first induction coil 160 and the second inductioncoil 170 have the same symmetry axis 107, and a ratio of dimensions ofthe first induction coil 160 and the second induction coil 170 is fromabout 1 to about 2. The first induction coil 160 and the secondinduction coil 170 has a gap G disposed therebetween, and the gap G isless than a radius of a smallest inscribed circle of the first inductioncoil 160 and the second induction coil 170.

For example, the shapes of the first induction coil 160 and the secondinduction coil 170 are circles, and the gap G is less than the radii ofthe first induction coil 160 and the second induction coil 170. Theradii of the first induction coil 160 and the second induction coil 170may be the same. Embodiments of this disclosure are not limited thereto.In other embodiments, the shapes of the first induction coil 160 and thesecond induction coil 170 may be other shapes, and the first inductioncoil 160 and the second induction coil 170 do not need to have the samesymmetry axis. The radius of the first induction coil 160, the radius ofthe second induction coil 170, and the gap G between the first inductioncoil 160 and the second induction coil 170 do not need to correspond toeach other as described above.

FIG. 4 is a schematic view of the rotating optical range finder 100according to another embodiment of this invention. As shown in FIG. 4,the rotating optical range finder 100 further includes a wireless signaltransmission module 180. The wireless signal transmission module 180includes a first part 182 and the second part 184. The first part 182 isdisposed in the stationary base 110 and electrically connected to thetransmitting circuit 140. The second part 184 is disposed in therotating base 120 and electrically connected to the receiving circuit150. The wireless signal transmission module 180 performs wirelesssignal transfer.

Specifically, the first part 182 and the second part 184 of the wirelesssignal transmission module 180 may be antenna, which emit or receiveradio wave signals. People having ordinary skill in the art can makeproper modifications to the wireless signal transmission module 180depending on the actual application. For example, in some embodiments, aplurality of optical data transmission devices such as IrDA (InfraredData Association) module can be used as the wireless signal transmissionmodule 180.

As shown in FIGS. 2 and 3, the rotating optical range finder 100 furtherincludes a light-emitting component 190, and the light-emittingcomponent 190 is disposed in the stationary base 110. The optical sensor130 includes a first reflector 132, a second reflector 134, alight-receiving lens 136, and an image sensor 138. The first reflector132 receives and reflects a light emitted by the light-emittingcomponent 190. The second reflector 134 receives a light reflected bythe first reflector 132 and reflects the light reflected by the firstreflector 132 to an object (not shown in figures). The light-receivinglens 136 collects a light reflected by the object. The image sensor 138detects a light collected by the light-receiving lens 136.

In the aforementioned configuration, the light-emitting component 190 isdisposed in the stationary base 110. Therefore, when the rotating base120 is rotating, the light-emitting component 190 does not rotate.Consequently, the light-emitting component 190 can provide stable laserbeam, such that the accuracy of the measurement is improved and that themeasurable distance is increased. In addition, because thelight-emitting component 190 is not disposed in the rotating base 120,the weight of the rotating base 120 is lessened, and the volume of therotating base 120 is reduced. Therefore, the rotating base 120 becomeseasier to rotate.

Specifically, the light-emitting component 190 is a collimated beamlaser module. People having ordinary skill in the art can make propermodifications to the light-emitting component 190 depending on theactual application.

In particular, the rotating base 120 has a first rotation axis, which isthe symmetry axis 107, and the light-emitting component 190 and thefirst reflector 132 are disposed on the first rotation axis. Peoplehaving ordinary skill in the art can make proper modifications to therotating base 120, the first reflector 132, and the light-emittingcomponent 190 depending on the actual application.

In this embodiment, the symmetry axis 107 and the first rotation axis isthe same axis. Embodiments of this disclosure are not limited thereto.other embodiments, the symmetry axis 107 and the first rotation axis maybe different axes.

The first reflector 132 may take the first rotation axis as the rotationaxis thereof, and the second reflector 134 has a second rotation axis108 and is able to conduct an orientation adjustment by rotating aboutthe second rotation axis 108. Specifically, the first rotation axis isperpendicular to the second rotation axis 108. People having ordinaryskill in the art can make proper modifications to the first reflector132 and the second reflector 134 depending on the actual application.

In particular, the rotating base 120 has a first through hole 122, andthe stationary base 110 has a second through hole 112. The first throughhole 122 and the second through hole 112 form a passage, such that thelight emitted by the light-emitting component 190 passes the passage andreaches the first reflector 132. The rotating base 120 further has athird through hole 124 to form a passage, such that the light reflectedby the first reflector 132 reaches the second reflector 134 by passingthe passage. As shown in FIGS. 1 and 2, the rotating base 120 furtherhas a fourth through hole 126 to form a passage, such that the lightcollected by the light-receiving lens 136 reaches the image sensor 138by passing the passage (in order to depict the fourth through hole 126,the light-receiving lens 136, the image sensor 138 clearly, an upperpart 128 of the rotating base 120 is not shown in FIG. 1).

As shown in FIGS. 2 and 3, after the light 200 is emitted by thelight-emitting component 190, the light 200 reaches the first reflector132 by sequentially passing the second through hole 112 and the firstthrough hole 122. Then, the light 200 is reflected by the firstreflector 132, and the reflected light 200 reaches the second reflector134 by passing the third through hole 124. Then, after the light 200 isreflected by the second reflector 134, the light 200 leaves the rotatingbase 120.

Because the first reflector 132 and the second reflector 134 can berotated to adjust the orientation thereof, the light 200 leaving therotating base 120 can be easily adjusted to be located in the plane inwhich the optical axis 139 of the light-receiving lens 136 is located,such that an angle θ between the light 200 leaving the rotating base 120and the optical axis 139 is fixed and that triangulation can beperformed. When the light 200 is emitted to an object, the light 200 isreflected by the object to form a reflected light (not shown infigures). Then, after the reflected light passes the light-receivinglens 136, the reflected light is focused to the image sensor 138.Therefore, the image sensor 138 can detect an angle between thereflected light and the optical axis 139, so as to calculate thedistance between the object and the symmetry axis 107 of the rotatingbase 120.

Embodiments of this disclosure are not limited thereto. In otherembodiments, the distance between the object and the optical sensor 130may be obtained by calculating the time difference between the leavingtime the light leaves the rotating base 120 and the receiving time theoptical sensor 130 receives the reflected light. In addition, thelight-emitting component 190 may be disposed in the rotating base 120 toemit a light to an object, and the optical sensor 130 detects the lightreflected by the object.

The rotating optical range finder 100 further includes a rotating module(not shown in figures). The rotating module, such as a motor, isdisposed in the rotating base 120 to drive the rotating base 120 torotate. Embodiments of this disclosure are not limited thereto. In otherembodiments, the rotating module can be disposed in the stationary base110. For example, the rotating module is a motor to drive a rubber band,and the rubber band is sleeved on the periphery of the rotating base120, such that the rubber band drives the rotating base 120 to rotate.

The rotating optical range finder 100 is continuously rotating when thedistances between the optical range finder 100 and the surroundings aremeasured. By performing wireless power transfer by the first inductioncoil 160 and the second induction coil 170, no other electric powertransfer component, such as a slip ring, is needed to be disposedbetween the stationary base 110 and the rotating base 120. Therefore,the weight of the rotating base 120 is lessened, and the volume of therotating base 120 is reduced. Moreover, because there is no physicalcomponent disposed between the stationary base 110 and the rotating base120 to perform electric power transfer, fractions between the stationarybase 110 and the rotating base 120 is lessened. Therefore the rotatingbase 120 becomes easier to rotate.

All the features disclosed in this specification (including anyaccompanying claims, abstract, and drawings) may be replaced byalternative features serving the same, equivalent or similar purpose,unless expressly stated otherwise. Thus, unless expressly statedotherwise, each feature disclosed is one example only of a genericseries of equivalent or similar features.

Any element in a claim that does not explicitly state “means for”performing a specified function, or “step for” performing a specificfunction, is not to be interpreted as a “means” or “step” clause asspecified in 35 U.S.C. § 112, 6th paragraph. In particular, the use of“step of” in the claims herein is not intended to invoke the provisionsof 35 U.S.C. § 112, 6th paragraph.

What is claimed is:
 1. A rotating optical range finder, comprising: astationary base; a rotating base disposed on the stationary base; anoptical sensor disposed in the rotating base; a transmitting circuitdisposed in the stationary base; a receiving circuit disposed in therotating base and electrically connected to the optical sensor; a firstinduction coil disposed in the stationary base and electricallyconnected to the transmitting circuit; and a second induction coildisposed in the rotating base and electrically connected to thereceiving circuit.
 2. The rotating optical range finder of claim 1,wherein the first induction coil and the second induction coil performwireless power transfer.
 3. The rotating optical range finder of claim1, wherein the first induction coil and the second induction coilperform wireless power transfer by magnetically coupled resonance. 4.The rotating optical range finder of claim 1, wherein the firstinduction end the second induction coil perform wireless signaltransfer.
 5. The rotating optical range finder of claim 1, wherein thefirst induction coil and the second induction coil have the samesymmetry axis.
 6. The rotating optical range finder of claim 1, whereina ratio of dimensions of the first induction coil and the secondinduction coil is from about 1 to about
 2. 7. The rotating optical rangefinder of claim 1 wherein the first induction coil and the secondinduction coil has a gap disposed therebetween, and the gap is less thana radius of a smallest inscribed circle of the first induction coil orthe second induction coil.
 8. The rotating optical range finder of claim1, further comprising a light-emitting component disposed in thestationary base, and wherein the optical sensor comprises: a firstreflector for receiving and reflecting a light emitted by thelight-emitting component; a second reflector for receiving a lightreflected by the first reflector and reflecting the light reflected bythe first reflector to an object; a light-receiving lens for collectinga light reflected by the object; and an image sensor for detecting alight collected by the light-receiving lens.
 9. The rotating opticalrange finder of claim 8, wherein the light-emitting component is acollimated beam laser module.
 10. The rotating optical range finder ofclaim 8, wherein the rotating base has a first rotation axis, and thelight-emitting component and the first reflector are disposed on thefirst rotation axis.
 11. The rotating optical range finder of claim 10,wherein the first reflector rotates about the first rotation axis, andthe second reflector has a second rotation axis and is configured toperform an orientation adjustment by rotating about the second rotationaxis.
 12. The rotating optical range finder of claim 11, wherein thefirst rotation axis is perpendicular to the second rotation axis. 13.The rotating optical range finder of claim 8, wherein the rotating basehas a first through hole, the stationary base has a second through hole,and the first through hole and the second through hole form a passage,such that a light emitted by the light-emitting component passes thepassage and reaches the first reflector.
 14. The rotating optical rangefinder of claim 1, further comprising a light-emitting componentemitting a light to an object, wherein the light-emitting component isdisposed in the rotating base, and the optical sensor detects a lightreflected by the object.
 15. The optical range finder of claim 1,further comprising a plurality of optical data transmission devices inboth the rotating base and the stationary base performing wirelesssignal transfer between the rotating base and the stationary base.